KR100997045B1 - Server rack - Google Patents

Abstract

PURPOSE: A server rack is provided to prevent the inflow of fine dust by forming a rack case into a dust shielding structure. CONSTITUTION: An information processing device and a server are stored inside a rack case(1). A door is formed in the front side of the rack case. A cable entrance port is formed in the back side of the rack case. A cooling chamber part(2) is combined in the side of the rack case. The evaporator of the cooling chamber part cools the air inside the rack case. A base chamber part(3) is combined under the rack case and the cooling chamber part. The base chamber part stores the condensed water generated in the evaporator of the cooling chamber part. A control chamber part(4) is combined under the rack case. The refrigerant compressor of the control chamber part circulates and condenses refrigerant.

Description

Server Rack {SERVER RACK}

The present invention relates to a server rack, and more particularly, to configure the server rack in a sealed structure to effectively prevent the dust-proof structure of the dust shield structure and the heat generation load inside the sealed dust shield structure without fear of dust intrusion therein. The present invention relates to a server rack equipped with a dustproofing and a cooling function, which are removed by a constant temperature and a cooling function of a constant temperature and a constant humidity.

In the present invention, the server rack refers to a server rack, a hub rack, and a communication rack made of a shelf on which various information processing devices such as a server or a hub are placed.

In general, the server rack is used to efficiently store a small space to accommodate, mount and secure the information processing devices in accordance with the requirements of the international standard (IEC), rack mounting various information processing devices such as servers and network equipment Frames and the like are provided for installation in a rack in a state accommodated in.

For reference, the rack mount method has a merit that the devices having respective functions can be freely configured according to the user's requirements by stacking them in layers for configuration and installation of information processing devices such as a server or a hub.

Such server rack information processing apparatuses generate heat by high integration and high performance, and if the heat load is not removed, it may cause fatal results such as system stoppage and failure. Accordingly, the general cooling method of the server rack is to form a separate computer room and remove the heat load by blowing the cooled air through the air conditioning unit inside the rack, and if the computer room cannot be operated separately due to cost, space, etc. An exhaust fan is provided in the rack to configure the heat load.

However, even if the computer room for the server rack is operated separately, the cooling air through the air conditioning unit must be supplied to the inside of the rack box, so there is no blocking method for dust inflow and the temperature due to the connection cable connection of various information processing devices and the heat island phenomenon in the computer room. In order to increase efficiency due to unbalanced control, the back of the server rack is often opened and in such a case, it is impossible to prepare for dust inflow.

Meanwhile, in a rack box (a cabinet where various information processing devices such as a server are installed), a blower fan that can be mounted in a rack box is miniaturized to save space when the information processing devices are mounted. If the server is not smooth, it can cause fatal damage to the server or the information processing device, resulting in economic loss and loss of data information.

As such, one of the major reasons for the failure of servers and information processing devices in server racks is the overload caused by temperature control failure. Therefore, in order to prevent the problem caused by the temperature rise in the rack, as described above, it is common to operate a computer room (server room) for removing heat generation in the rack, which will be described in detail below.

The computer room where the server rack is installed supplies air for heat load removal inside the computer room by centralized cooling to control the temperature inside the room. The server rack in the computer room has perforated plates on the side to smoothly supply and remove the air inside the rack. Using it will be made for sufficient ventilation. Therefore, in order to remove heat generation in the server rack, it is necessary to remove heat generation in the entire interior of the computer room, which has a disadvantage in that energy loss is very large.

In addition, it does not supply sufficient airflow to the high-density server, and the heat of the rear of the rack is recirculated to the inlet of the front of the rack, and thus it is impossible to remove the heat load in the rack and the excessive investment and management of the computer room operation and management. The cost of manpower is incurred.

In addition, the server rack in the computer room as well as the server rack of the basic method has a structure that allows forced cooling air to enter and exit the inside of the rack by using a perforated plate to increase the ventilation area for heat exchange of the rack itself for temperature management. Should be Therefore, due to this supply / exhaust method, constant temperature and humidity can be managed separately by computer room, but problems such as leakage, spark, malfunction of equipment, hard disk error due to static electricity caused by fine dust flowing into rack box Despite its operation and management, its occurrence is high.

As such, the fine dust (carbon, zinc, organic fine particles, etc.) is a fatal factor that causes short circuits or line failures, resulting in server or equipment failure. The back surface is opened and operated for cable wiring and monitoring. Since there is no choice but to have a ventilation structure for the existing server rack structure, these problems are always faced regardless of the operation of the computer room.

The technology for cooling the rack box has been variously developed as follows, but the technology of shielding the inflow of dust and applying the cooling function at the same time cannot be identified.

Japanese Laid-Open Patent Publication No. 2004-63755 supplies cool air blown from an air conditioning unit to a lower air supply port of a rack, which cools the equipment in the rack, and simultaneously airs the exhaust from the exhaust port on top of the rack warmed by the equipment. A cooling structure of a rack for returning to a unit and circulating is disclosed.

In addition, Japanese Laid-Open Patent Publication No. 2006-93388 supplies cold air from a cooler unit to a downflow unit detachably installed on the upper front side of the server rack via an exchange panel, and the cold flow force is forced downward by the downflow unit. A cooling device for a server rack is disclosed, which blows in to cool an electronic device and exhausts the waste heat of the cooler unit to the outside through an outdoor exhaust duct.

Korean Patent Laid-Open Publication No. 10-2010-0019308 discloses a fan unit arranged with a plurality of fans for discharging heat generated from a heat source from a rack, and a pipe for guiding a refrigerant to heat the heat discharged from the rack by the rotation of the fans. And a heat exchanger comprising a radiator unit in which the fan is arranged, a frame unit integrally forming the fan unit and the radiator unit, a rack mounted on an exhaust surface side of the rack, and a hose for distributing a refrigerant connected to the pipe. A cooling system of the device is disclosed.

Korean Patent Publication No. 10-2004-73983 discloses a plurality of server modules in which a main circulation pipe, a main circulation pump and a cooling unit are installed in a rack cabinet, cooled through the main circulation pipe, and a heat receiving unit and an internal pump are installed. The cooling method of the rack mount server system that connects the main circulation pipes in parallel to supply and drain the coolant and to cool the heat generating parts in each server module to adopt the liquid cooling method to smoothly dissipate the high heat generating components mounted in the server module. have.

Meanwhile, Patent Document 1 (Korean Patent Laid-Open Publication No. 10-2005-0084871) consists of a cabinet completely surrounding a rack unit, and forms a plenum between the rack unit and the rack to fill the filler material therein, thereby making noise from the sound absorbing material. The server rack which aimed at blocking is disclosed.

The server rack of the patent document 1 is equipped with a cooling device consisting of a combined air and liquid heat exchanger on one side of the cabinet, but the closed structure is surrounded by a filler material for the purpose of blocking noise by the sound absorbing material, It is only a cooling function aimed at preventing recirculation, and it is insufficient as an efficient cooling device for server racks requiring constant temperature and humidity, and it is impossible to shield the inflow of fine dust by filler material. .

Republic of Korea Patent Publication No. 10-2005-0084871, 2005.08.29.

The rack-mounted server rack is preferred and widely used as above, but it does not have its own cooling function, so it is not possible to have a huge burden of energy consumption in the operation of the computer room by operating a separate computer room for constant temperature maintenance. If not, the server and information processing devices are operated in the empty space inside the office or factory building with risks, or even when the computer room is operated separately, malfunctions or failures due to the inflow of fine dust The problem cannot be solved.

To solve this problem, it is most desirable to configure the server rack as a dust shield structure, but the dust shield structure should be a ventilation structure to remove heat generation, power line, optical cable entry, UPS, distributor, RJ-25 (communication), Due to the wiring and connection of various information processing devices such as servers, the back of the rack box can be operated almost in an unopened state, and thus problems such as malfunctions or failures exposed to the above-described fine dust cannot be solved.

On the other hand, the closed structure of the sound insulation purpose disclosed in Patent Document 1 also has a focus on preventing the recirculation of hot air and has a closed structure, but can not prevent the inflow of fine dust by the internal filler material, which is one of several purposes of the present invention Dust shielding structure can not be achieved, and under the dust shielding structure, it is not able to provide efficient cooling function, constant temperature, and humidity function inside the sealed enclosure.

Accordingly, in the present invention, the server rack is configured as a dust shield structure by modularizing a power line inlet, an optical cable inlet, a splitter, and an RJ-25 jack of the server rack for a shield structure in the server rack. Make sure there are no problems.

In addition, the dust shielding structure to block the inflow of fine dust in the inside of the server rack to solve the problem caused by the fine dust.

In addition, by providing a humidifying effect with the supply of cooling air inside the server rack made of the dust shield structure to supply high-quality air at constant temperature, constant humidity (恒 濕) can be generated by the heating load To solve the above problems and to make the server rack more stable and efficient operation and management.

In addition, to minimize the energy consumption in the heat exchange process to reduce the energy required to cool the server rack.

The present invention for solving the above problems;

According to the invention as set forth in claim 1, there is provided a rack for storing the information processing apparatus and the server in a stack therein, a door for opening and closing the inside of the front, and a rack box having a cable entry in the rear; A cooling chamber part coupled to the side of the rack box and having an evaporator installed to suck and cool air in the rack box; A water storage chamber part coupled to the rack and a lower portion of the cooling chamber part, the condensate generated by the evaporator of the cooling chamber part is naturally dropped and stored, and the water chamber part which blows the cooled air of the cooling chamber part into condensate and blows it into the rack; A control chamber part coupled to the bottom of the rack box and having a refrigerant compressor configured to circulate, condense, and supply the refrigerant to a condenser condenser condensing the evaporator of the cooling chamber part and the refrigerant of high temperature and high pressure; Characterized in that consisting of a condenser chamber part is installed a condenser for radiating, condensing the refrigerant.

According to the invention described in [claim 2]; The method of claim 1, wherein the suction port is formed in communication with the cooling chamber part on the side of the rack compartment and a suction fan is installed to suck the air inside the rack compartment into the cooling chamber part, the water storage chamber part in the lower portion of the cooling chamber part The condensate generated from the evaporator of the cooling chamber part is naturally formed to form a drain plate (DRAIN PAN), and the water chamber part is in communication with the rack box through the air vents so that the cooling air of the cooling chamber part through the drain plate rack It is characterized by allowing the air to blow.

According to the invention described in [claim 3]; The condensate evaporation fan of claim 1, wherein a condensate evaporation fan is formed between the refrigerant compressor and the condenser.

According to the invention described in [claim 4]; According to claim 3, wherein the condensation evaporation fan is connected to the drain plate and the condensate recovery pipe of the water storage chamber part characterized in that the condensate of the drain plate is naturally introduced into the condensation evaporation fan by the gradient difference (句 配). .

According to the invention described in [claim 5]; The condenser chamber part of claim 1, wherein the control chamber part is provided with an air inlet and a blower fan for introducing the outside air to blow the outside air into the condenser chamber part to radiate the condenser. It is characterized by configured to open the top for.

The present invention constitutes a rack box of a dust shield structure to fundamentally block inflow of fine dust and the like, and simultaneously solves problems caused by dust inflow and heat load by simultaneously providing a cooling function by cooling and circulating air caused by a heat load. Can and

In particular, the server rack can be operated and managed under optimal conditions by supplying high quality air with constant temperature and humidity by the humidification function, and it can be expected to have economic benefits by greatly reducing the energy consumption required for the cooling function. have

1 is an overall perspective view showing an embodiment of the present invention.
2 is a perspective view illustrating an isolated state of the present invention.
3 is a front view of the present invention.
4, 5 and 6 are back, side and plan views of the present invention.
7, 7a is a perspective view showing the configuration of a rack box in the present invention.
8 is an enlarged cross-sectional view of a part of the rack box of the present invention.
9 is a configuration diagram of a cooling chamber part of the present invention.
10 and 10a are schematic diagrams of the storage chamber parts of the present invention.
11 is a configuration diagram of a control chamber part of the present invention.

The present invention is to configure the server rack with a dust shield structure to provide a dust-proof function to block harmful factors caused by dust, such as organic particulates, and to provide a cooling function for removing the heat load in the shielded server rack. It is a server rack.

The rack has a structure in which a frame capable of stacking and storing the information processing apparatus and the server is installed in a structure that allows compatible mounting according to IEC standards, etc., and a door for opening and closing the rack is installed at the front of the rack. An upper side of the rack box is formed with an inlet for sucking air in the rack, and a bottom is formed with a vent for blowing cooling air into the inside of the rack.

The rear of the rack box forms an inlet of various cables such as a power line, a communication line, and an optical cable to form a sealed structure inside the rack.

One side of the rack box is coupled to the cooling chamber part in communication with the upper side outlet. The cooling chamber part is provided with a suction fan for suctioning the air inside the rack from the upper side outlet of the rack, and an evaporator (EVAPORATION) for cooling the sucked air is installed in the lower portion of the cooling chamber.

And the lower portion of the cooling chamber part is combined with the storage chamber part that the condensate generated in the evaporator of the cooling chamber part is naturally dropped and stored.

The reservoir chamber part is coupled to the bottom of the cooling chamber part to store the condensed water in the drain plate (DRAIN PAN) of the reservoir chamber part, and the rest is coupled to the bottom of the rack box formed with a vent hole through the drain box rack and cooling chamber Communicate parts.

In addition, a control chamber part is coupled to the bottom of the rack, and the control chamber part is coupled over the condenser chamber part described later. The control chamber part is provided with a refrigerant compressor (COMPRESSOR) for circulating and supplying the refrigerant to the condenser of the evaporator of the cooling chamber part and the condenser chamber part.

In addition, a condensate evaporation refrigerant line is formed between the refrigerant compressor and the condenser so as to pass through the condensate evaporation fan, and the condensation evaporation fan is connected to the drain plate of the water storage chamber part and the condensate return pipe to condense the condensate on the drain plate. The difference allows natural inflow into the condensate evaporator fan.

The condenser connected to the refrigerant compressor is installed in the condenser chamber part, and the condenser chamber part is configured by opening the upper part for heat dissipation of condensation heat of the condenser.

In addition, the control chamber part is formed with an air inlet and a blower fan for introducing the outside air to blow the outside air into the condenser chamber part to radiate the condenser.

Hereinafter, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is an overall perspective view showing an embodiment of the present invention, Figure 2 is a perspective view illustrating the separation of the present invention, Figure 3 is a front view of the present invention, Figure 4 is a rear view of the present invention, Figure 5 is the present invention 6 is a plan view of the present invention, Figure 7, 7a is a perspective view showing the configuration of the rack box of the present invention, Figure 8 is an enlarged partial cross-sectional view of the rack box of the present invention, Figure 9 is a configuration of the cooling chamber part of the present invention 10 and 10A are schematic diagrams of the storage chamber part of the present invention, and FIG. 11 is a schematic diagram of the control chamber part of the present invention.

Rack box (1) is installed in the frame so as to be compatible with various information processing devices and servers in accordance with the IEC standards therein, the front door 11 is coupled to open and close the upper side of the cooling chamber parts ( A suction port 12 is provided to suck at 2), and a blower 13 is formed at a bottom thereof to blow cooled air into the rack box 1.

The front door 11 of the rack box 1 is coupled to the door 11 made of a transparent material (tempered glass or Daejin acrylic plate, etc.) so as to open and close the door 11 so that the state of the internal server and the information processing apparatus can be visually seen. In order to be able to observe without opening, and to install a plurality of servers, the distributor 15 is mounted so that a work for monitoring and adjusting by each server is possible so that the selection by server at any time is possible. Distributors (15) are generally configured to select each server through a selector button or the like, and a monitor 11 is mounted on the door 11 of the rack box 1 to monitor as needed. Can be.

In addition, the cable entry port 14 and 14 'are formed on the rear surface of the rack box 1 to form various cables such as a power line, a communication line, and an optical cable as shown in FIG. By connecting to the server and the information processing devices through the (14, 14 ') to seal the inside of the rack box 1 is configured in a dust shield structure.

To this end, the rack box (1) is configured to process the information about the arrangement of the server and the information processing apparatus at the time of manufacturing the power cable inlet (14, 14 '), the inlet (15, 15') for the entrance of the communication line accordingly do.

The closed rack box (1) has a dust shielding structure in which dust inflow is blocked from the outside to fundamentally solve problems such as failure or malfunction due to dust.

The side of the rack box 1 is coupled to the cooling chamber part (2) in communication with the side upper inlet (12). The cooling chamber part 2 communicates with the upper side suction port 12 of the rack box 1 and forms an inlet port 22 for sucking the air in the rack box 1 from the suction port 12 and a suction fan at the suction port 22. Install (21). An evaporator 23 for cooling the air sucked inside the rack box 1 is installed in the lower portion of the cooling chamber 2 in which the suction fan 21 is installed at the suction port 22.

The evaporator 23 is to obtain the cooled air through heat exchange between the refrigerant and the air, the configuration of such an evaporator 23 is common. (FINE & TUBE TYPE, etc.)

And the lower portion of the cooling chamber part (2) combines the water storage chamber part (3) in which the condensed water generated in the evaporator of the cooling chamber part (2) is naturally dropped and stored. The water storage chamber part 3 is coupled to communicate with a lower portion of the cooling chamber part 3 to condense water generated in the evaporator 23 on a drain plate 31 formed over the water storage chamber part 3. To be stored.

In addition, the rest of the water storage chamber part 3 coupled to the cooling chamber part 2 is coupled to the bottom surface of the rack box (1). The water storage chamber part 3 has a drain hole 32 formed in communication with the air hole 13 of the bottom surface of the rack box 1 to be coupled to the bottom of the rack box 1 and the drain plate formed over the water storage chamber part 3 ( The air cooled through the evaporator 23 of the cooling chamber part 2 by the rack box 1 and the cooling chamber part 2 through 31 is blown holes 32 and 13 through the drain plate 31. Blowing through the rack (1) through.

That is, the air inside the rack box 1 is sucked with the cooling chamber part 2 through the inlet 12 to exchange heat with the evaporator 23, and the air cooled by the heat exchange is the storage chamber part 3 as the transfer passage. It is to be introduced into the rack (1) again through the vents (32) (13).

In particular, the condensate accumulated in the drain plate 31 by evaporative heat exchange in the above process humidifies the cooling air that has passed through the evaporator 23 at all times, unlike the general cooling cycle, to supply air of constant temperature and constant humidity into the rack box 1. do.

That is, unlike the general cooling cycle, the cooling air passing through the evaporator 23 passes through the condensate surface stored in the drain plate 31 while passing through the drain plate 31 in which the condensate is stored. Brings an increase.

For example, if the air inside the rack box (1) is managed at a recommended temperature of 22-25 ° C, the air blown back through the evaporator (23) to the surface of condensate and then blown back into the rack (1) is 50% relative humidity. By supplying 5% of constant quality air, it provides humidity control with its own temperature control (air cooling) to maintain constant humidity with evaporation of condensate.

On the other hand, the bottom of the rack (1) refrigerant compressor (COMPRESSOR) 41 for circulating and supplying the refrigerant to the condenser (CONDENSER) 51 of the evaporator 23 of the cooling chamber part (2) and the condenser chamber part (5) Coupling the control chamber part (4) provided with the back.

The refrigerant compressor 41 is connected to the evaporator 23 and the capillary tube 24 of the cooling chamber part 2 and the condenser 51 of the condenser chamber part 5 to circulate and condense the refrigerant. By condensation, the condensation water vaporization refrigerant line 52 is formed between the refrigerant compressor 41 and the condenser 51 so as to pass through the condensation water vaporization fan 42.

The condensate evaporation fan 42 is connected to the drain plate 31 and the condensate return pipe 34 of the water storage chamber part 3 so that the condensed water of the drain plate 31 is condensed due to the pressure difference due to the gradient. Allow natural inflow into the evaporation fan (42). The condensation water evaporation refrigerant line 52 between the refrigerant compressor 41 and the condenser 51 is configured as a part of the condenser 51, and is arranged in a zigzag form in the condensation water evaporation fan 42 to form a drain plate 31. By condensing the condensate introduced from the condensate to help the cooling of the condenser 51 will contribute to energy saving.

That is, in the condensate evaporation fan 42 into which the condensed water is introduced, the condensate evaporation refrigerant lines 52 are arranged in a zigzag form so that the high temperature and high pressure refrigerant compressed by the refrigerant compressor 41 exchanges heat with the condensate to evaporate the condensate. Let's go.

The rack box (1) is composed of a cooling of the closed circulation structure is less generated condensate water and accordingly evaporated to remove the condensate generated in the condensate evaporation fan 42, there is no need for a separate facility for condensate treatment.

On the other hand, it is possible to consider the case of excessive condensate (although the practicality is low in terms of the operating temperature conditions inside the rack) In such a case, the condensate may be absorbed inside the drain pan 31 of the water storage chamber part 3. It may be possible to introduce an absorbent cartridge.

In addition, even if not completely evaporated condensate water provides the primary effect of the water-cooled condensation to cool the condenser 51, the heat dissipation of the condenser 51 by the second air cooling after the first heat dissipation by water cooling to greatly save energy required It can contribute.

The condenser 5 connected to the refrigerant compressor 41 is installed in the condenser chamber part 5 and the air cooling process is performed after the water cooling process. The condenser chamber part 5 is located on the side of the rack box 1 and the control chamber part 4. ) It is installed in communication with the control chamber part (4) on the upper side.

The condenser chamber part 5 forms an opening 53 by opening an upper portion for heat dissipation of the condenser 51, and the control chamber part 4 has an outside air inlet 44 for introducing air. And a blower fan 43 to blow the outside air sucked into the condenser chamber part 5 to dissipate the condenser 51.

Therefore, the condenser 51 is to significantly reduce the energy consumption for the heat dissipation of the condenser 51 by the double condensation heat exchange is made of heat condensation heat exchanged with the secondary air after the heat dissipation by the above-described water cooling.

In order to explain the embodiments of the present invention in detail, reference numerals used in the accompanying drawings are as follows.
1: rack box 11: door
12: Intake 13: Blower
14.14 ': Cable entry 16: Sealing gate
2: Cooling chamber part 21: Suction fan
22: inlet 23: evaporator
24: capillary tube
3: Water chamber part 31: Drain board
32: air vent 33: collection pipe
4: control chamber part 41: refrigerant compressor
42: condensation evaporation fan (PAN) 43: blowing fan
44: outside air entrance
5: condenser chamber part 51: condenser
52: condensation evaporation refrigerant line 53: opening

Claims (5)

A rack box having a frame capable of stacking and storing the information processing apparatus and the server therein and having a door configured to open and close the inside at a front side thereof;
A cooling chamber part coupled to the side of the rack box and having an evaporator installed to suck and cool air in the rack box;
A water storage chamber part coupled to the rack and a lower portion of the cooling chamber part, the condensate generated by the evaporator of the cooling chamber part is naturally dropped and stored, and the water chamber part which blows the cooled air of the cooling chamber part into condensate and blows it into the rack;
A control chamber part coupled to the bottom of the rack box and having a refrigerant compressor configured to circulate, condense, and supply the refrigerant to a condenser condenser condensing the evaporator of the cooling chamber part and the refrigerant of high temperature and high pressure;
Server rack, characterized in that consisting of a condenser chamber part is installed a condenser for radiating and condensing the refrigerant. The method of claim 1,
A suction port communicating with the cooling chamber part is formed on the side of the rack box, and a suction fan is installed to suck the air inside the rack box into the cooling chamber part.
In the storage chamber part below the cooling chamber part, a condensate generated from the evaporator of the cooling chamber part is naturally formed to form a drain plate (DRAIN PAN).
The water storage chamber part is in communication with the rack box through the air outlet so that the cooling air of the cooling chamber part is blown into the inside of the rack box via the drain plate. The method of claim 1,
Server rack, characterized in that formed between the refrigerant compressor and the condenser condensate evaporation fan via the condensate evaporation refrigerant line. The method of claim 3, wherein
The condensate evaporation fan is connected to the drain plate and the condensate return pipe of the reservoir chamber part to allow the condensed water in the drain plate to naturally flow into the condensation evaporation fan due to the gradient difference. The method of claim 1,
The control chamber part is formed with an air inlet and a blower fan for introducing the outside air to blow out the outside air to the condenser chamber part to dissipate the condenser.
The condenser chamber part is installed the condenser server rack, characterized in that configured to open the top for heat dissipation of the condenser.

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